Electronic pressure and temperature sensor for a fluid media

ABSTRACT

An electronic pressure and temperature sensor includes a chamber disposed within a housing. The pressure and temperature sensor are disposed at a chamber first end. An opening is disposed at a chamber second end, wherein the opening is configured to be in fluidic communication with the fluid media. A viscous gel is disposed within a portion of the chamber and encloses the pressure and temperature sensor apart from the fluid media. A second temperature sensor is at least partially disposed within the housing and is not disposed within the chamber. The first temperature sensor is configured to measure a temperature of the viscous gel, where the temperature of the viscous gel configured for use in temperature compensation calculations used to determine the pressure of the fluid media. The second temperature sensor is configured to measure a temperature of the flow of the fluid media.

CROSS-REFERENCE TO RELATED APPLICATIONS

This continuation application claims priority to continuation-in-part application Ser. No. 16/590,678 filed on Oct. 2, 2019, which will issue as U.S. Pat. No. 11,047,756 on Jun. 29, 2021; which itself claims priority to non-provisional application Ser. No. 15/453,756 filed on Mar. 8, 2017, which is U.S. Pat. No. 10,458,872 issued on Oct. 29, 2019; which itself claimed priority to provisional application 62/306,002 filed on Mar. 9, 2016, the entire contents of which all applications are fully incorporated herein with these references.

DESCRIPTION: Field of the Invention

The present invention generally relates to pressure sensors. More particularly, the present invention relates to a pressure sensor using a viscous gel that reduces manufacturing costs.

Background of the Invention

Electronic pressure sensors are used to measure the pressure of fluid media, such as gases, liquids or combinations thereof. Some of the fluid media such as water causes damage to the electronic components of the pressure sensor. Traditionally to prevent fluid media damage to the vulnerable electrical and electronic components of an electronic pressure sensor these components are shielded by a metallic (usually stainless steel) diaphragm. This diaphragm is a thin metallic sheet that transfers the fluid media pressure to the electronic (sensor bridge) components of the sensor through a nonabrasive type of oil that is filled in the body of the sensor housing. These devices are made with stainless steel body and usually referred to as “oil filled” sensors. Manufacturing of oil filled sensors is a multi-operational and expensive process.

With emergence of automated and connected devices, demand for water pressure sensors have drastically increased but the relatively high price of traditional oil filled sensors prevents their use in many high-volume applications.

There are a multitude of prior art teaching various alternatives to the oil filled option, but these are neither practical nor economical. Furthermore, the prior art doesn't teach a solution to monitor the true fluid media temperature and pressure in the same embodiment. Additionally, the prior art doesn't safeguard against erosion of the pressure transmitting gel against water flow, i.e., they have been targeted towards stagnant fluid media and not to be installed in the path of flowing fluid media.

Accordingly, there is a need for a new type of pressure sensor that is cheaper to manufacture and doesn't erode with the use of a flowing fluid media.

SUMMARY OF THE INVENTION

An exemplary embodiment of an electronic pressure sensor includes: a housing comprising a distal end configured to be exposed to a flow of a fluid media to be measured, the distal end opposite a proximal end, wherein the proximal end is configured not to be exposed to the fluid media; a chamber disposed within the housing; a passageway disposed within the housing, the passageway connected at one end to the chamber and connected at another end to an opening disposed at the distal end of the housing, wherein the opening is configured to be in fluidic communication with the fluid media; a pressure sensor disposed within the chamber; a first temperature sensor disposed within the chamber; and a viscous gel disposed within the chamber, the viscous gel separating on a first side both the pressure sensor and the first temperature sensor apart from the passageway on a second side of the viscous gel.

In other exemplary embodiments the chamber may define at least one inner sidewall, wherein the viscous gel fully and continuously in is contact with the at least one inner sidewall. The viscous gel may fully enclose and may be in contact with the pressure sensor and the first temperature sensor. The viscous gel may be configured to prevent the fluid media from contacting the pressure sensor or first temperature sensor. The viscous gel may not be disposed within the passageway. The viscous gel may not fully fill the chamber forming an empty space of the chamber to reside connected to the passageway. In other words, an empty space is created within the chamber such that the empty space does not have the viscous gel disposed within, preventing the viscous gel from touching the end of the chamber and causing errors in the pressure sensor reading.

The housing may be an injection molded polymer housing and may be clear or translucent. Then, the viscous gel may be colored.

A second temperature sensor may be disposed within the housing and at least partially exposed at the distal end of the housing to the fluid media, wherein the second temperature sensor is not in fluidic communication with the passageway or the chamber, but the second temperature sensors is in fluidic communication with the fluid media. The pressure sensor may be an electronic bridge pressure sensor.

The pressure sensor and the first temperature sensor may be both mounted onto a circuit board, wherein the circuit board is attached to the housing.

The circuit board may seal a first end of the chamber. The second end of the chamber is in fluidic communication with the passageway. The first end and second end of the chamber are delimited by the at least one inner sidewall.

A cross section taken perpendicularly through the at least one inner sidewall defines a chamber cross sectional area, wherein the chamber cross sectional area may be larger or at least three times larger than an area of the pressure sensor exposed to the viscous gel.

A seal may be formed around the housing, the seal separating the distal end of the housing from the proximal end of the housing, wherein the seal is configured to seal to a fluid pipe containing the fluid media when the electronic pressure sensor is connected to the fluid pipe.

The passageway disposed within the housing may define a passageway length, the passageway length extending at the one end of the chamber to the opening disposed at the distal end of the housing, wherein the length is at least 5 times an average diameter or an average width of the passageway.

Other features and advantages of the present invention will become apparent from the following more detailed description, when taken in conjunction with the accompanying drawings, which illustrate, by way of example, the principles of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings illustrate the invention. In such drawings:

FIG. 1 is a top side perspective view of an exemplary embodiment of the present invention;

FIG. 2 is a bottom side perspective view of the structure of FIG. 1;

FIG. 3 is a side view of the structure of FIG. 1;

FIG. 4 is a sectional view through the structure of FIG. 1 along the same side view as FIG. 3;

FIG. 5A is a perspective view of one embodiment of a chamber shape of the present invention;

FIG. 5B is a sectional view taken from lines 5B-5B of FIG. 5A;

FIG. 6A is a perspective view of another embodiment of a chamber shape of the present invention;

FIG. 6B is a sectional view taken from lines 6B-6B of FIG. 6A;

FIG. 7A is a perspective view of yet another embodiment of a chamber shape of the present invention;

FIG. 7B is a sectional view taken from lines 7B-7B of FIG. 7A;

FIG. 8 is a sectional view of just the housing of the structure of FIG. 1 similar to that shown in FIG. 4;

FIG. 9 is a sectional view similar to FIG. 5 now showing another embodiment of the housing;

FIG. 10 is a sectional view similar to FIG. 5 now showing another embodiment of the housing;

FIG. 11 is a typical velocity profile as seen through a section of a circular pipe;

FIG. 12 is also shows two different velocity profiles for two different sized pipes with the same flow rate;

FIG. 13 is a sectional view of the housing of the present invention;

FIG. 14 is an enlarged sectional view taken along lines 14-14 from FIG. 13;

FIG. 15 is a sectional view of a new embodiment of a housing of the present invention; and

FIG. 16 is a sectional view of another new embodiment of a housing of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 is a top side perspective view of an exemplary embodiment of a novel electronic pressure sensor 10. FIG. 2 is a bottom side perspective view of the structure of FIG. 1 and FIG. 3 is a side view of the structure of FIG. 1. The pressure sensor 10 can be best understood when looking at FIG. 4, which is a sectional view through the structure of FIG. 1 along the same side view as FIG. 3. FIG. 4 can also be understood as taken from lines 4-4 from FIG. 1. (As used herein, the fluid media includes liquids, gasses or combinations thereof. Also, the fluid media may be referred to simply as the fluid or as the media, as these terms are interchangeable with one another.)

A housing 12 comprises a distal end 14 that is configured to be exposed to a flow of the fluid media to be measured. Opposite the distal end 14 is a proximal end 16, wherein the proximal end is configured not to be exposed to the flow of the fluid media. A seal 18 disposed within seal channel 19 is used to prevent the flow of the fluid media from exiting the pipe or conduit which contains the flow and separates which part of the housing is exposed to the flow and which part of the housing is outside of the flow of the fluid media. The seal 18 may be a gasket, O-ring, plumber's tape, curable adhesive or the like. The seal 18 may be one seal, or a multitude of seals 18 that are placed within a multitude of channels 19, as shown later in FIGS. 15 and 16.

A chamber 20 is disposed (formed/made) within the housing 12 having a chamber volume 20 v. The chamber volume 20 v is defined by a chamber area 21 extending along a chamber length 20 c. The chamber area 21 is formed from a chamber perimeter 43 having at least one chamber inner sidewall 44. The chamber can also have a width 20 d or a diameter 20 d. The chamber length 20 c extends between a chamber first end 20 a and a chamber second end 20 b.

A passageway 22 is also disposed (formed/made) within the housing 12. The passageway 22 is connected at one end 22 a to the chamber 20 and the passageway 22 is connected at another end 22 b to an opening 24 disposed at the distal end 14 of the housing 12. The opening 24 is configured to be in fluidic communication with the flow of the fluid media.

A circuit board 26 includes a pressure sensor 28 and a first temperature sensor 30. The pressure sensor 28 and temperature sensor 30 are mounted onto the circuit board, where when the circuit board is attached to the housing 12, the pressure sensor 28 and the temperature sensor are exposed to the chamber 20. A second seal 32 may be used to seal the chamber 20. The second seal may be a gasket, O-ring, curable adhesive or the like. In this case a backing plate 34 abuts the circuit board and is held in with fasteners 36. As shown herein, electronic wiring 38 can then run from the circuit board 26 to any associated electronic processors or the like. It is understood that the circuit board 26 seals a first end 20 a of the chamber 20 and a second end 20 b of the chamber 20 is in fluidic communication with the passageway 22. The pressure sensor 28 may be an electronic bridge pressure sensor.

As shown in FIG. 4, a viscous gel 40 is disposed within the chamber 20. The viscous gel 40 separates on a first side (20 a) both the pressure sensor 28 and first temperature sensor 30 apart from the passageway 22 on a second side (20 b) of the viscous gel 40. The viscous gel 40 fully encloses and is in contact with the pressure sensor and the first temperature sensor. The viscous gel 40 is configured to prevent the fluid flow from contacting the pressure sensor or the first temperature sensor. As can be seen in FIG. 4, the viscous gel 40 is not disposed within the passageway 22. Furthermore, the viscous gel 40 does not fully fill the chamber forming an empty space 42 of the chamber 22 to reside connected to the passageway 22. The empty space fills up with the fluid media from the flow when the pressure sensor is in use.

The viscous gel can also be described as a highly viscous pressure transmitting gel that also insulates the electronic components from the fluid media. The viscosity of the proposed gel is within a range that its viscosity can be measured by the use of a penetrometer. The viscosity can be 465 cP plus or minus ten percent (10%). In other embodiments, the viscosity can range plus or minus 50 percent (50%). The symbol cP is the shorthand representation for centipoise, which is a common unit of measurement for viscosity. The poise (symbol P) is the unit of dynamic viscosity in the centimeter-gram-second system of units and received its named after Jean Leonard Marie Poiseuille. The poise is often used with the metric prefix “centi” because the viscosity of water at 20° C. is almost exactly 1 centipoise. A centipoise is one hundredth of a poise.

It is also important that the viscous gel 40 be free of air bubbles such that the pressure is properly transmitted through the viscous gel and into the pressure sensor. Therefore, when the gel is deposited or placed into the chamber 20 care should be taken to minimize or eliminate excess bubble formation.

The chamber 20 can take many shapes and sizes. FIGS. 5A, 6A and 7A are simplistic perspective views of the varying shapes and sizes that the chamber 20 can take. The chamber 20 can take many forms, as these figures are merely just a few of the various embodiments that one skilled in the art could use to practice the invention. The first end 20 a and the second end 20 b of the chamber 20 are delimited (enclosed) by at least one inner sidewall 44. As can be seen, FIG. 5A is rectangular/square in shape and has four sidewalls 44, FIG. 6A is cylindrical in shape and has one continuous sidewall 44 and FIG. 7A is triangular in shape and has three sidewalls 44. It is important to understand that the when the viscous gel 40 is in the camber 20, the viscous gel fully and continuously in is contact with the at least one inner sidewall 44 along a portion thereof of the perimeter, thereby sealing the fluid to be measured from the sensors. This prevents the fluid flow from bypassing the viscous gel and contacting directly the electronics on the circuit board 26 such as the pressure sensor 28 and the temperature sensor 30.

If one was to take a sectional view through the chambers of FIGS. 5A, 6A and 7A the result is an area which is respectively depicted in FIGS. 5B, 6B and 7B. Each shape has a corresponding chamber area 21. It is important that the cross-sectional area of the chamber is larger than the area of the pressure sensor. This is because the viscous gel has a certain viscosity which causes it to adhere or attach to the inner sidewall 44. If the area of the chamber was not large enough, the viscous gel resists the pressure building up in the space 42 to a great degree and prevents uniform pressure of the fluid flow from being transmitted to the pressure sensor. As the area of the chamber gets large enough, pressure can be correctly transmitted through the viscous gel and into the pressure sensor. The area of the chamber should always be at least 3 times or more (e.g. 4, 5, 6, etc.) larger than the pressure sensing area of the pressure sensor itself.

It is also important to understand that when the viscous gel 40 partially fills a chamber, the viscous gel is fully in contact with all of the sides of the chamber such that the fluid does not reach the pressure sensor 28 and temperature sensor 30. In the case of FIG. 6A-B, the inner sidewall 44 is a cylinder, so the viscous gel would fully be in contact with the entire chamber perimeter 43 of the inner sidewall 44 while still leaving an empty space 42. Likewise, when referring to FIGS. 5A-B, the chamber has four inner sidewalls 44, such that the viscous gel would be contacting each of the four inner sidewall along an entire perimeter of the chamber while still providing for the empty space 42. Finally, when referring to FIGS. 7A-B, the chamber has a triangular shape where there are three inner sidewalls 44, such that the viscous gel would be contacting each of the three inner sidewalls along an entire perimeter of the chamber while still providing for the empty space 42. Those skilled in the art can now appreciate how any sided chamber would have the viscous gel fitted within, such as for chambers with 5, 6, 7 or “n” number of inner sidewalls 44.

As shown in FIGS. 8, 9 and 10, the passageway 22 can take on many shapes. The passageway is a narrow channel that leads into the chamber. The passageway is sized smaller than the chamber such that any fluid flow does not erode away the viscous gel. As can be understood, the passageway allows the pressure of the fluid flow to be transmitted into the chamber while preventing the turbulence of the fluid flow from entering the chamber. This is turn prevents the fluid flow from eroding away the viscous gel. The diameter of the passageway is minimized to prevent erosion of the gel due to the media flow and pressure variations in the media, but it also prevents direct contact to the media from the electronics of the circuit board.

FIG. 8 is the same housing as is shown in FIG. 4, where the passageway 22 has the same area along its length. FIG. 9 has a passageway 22 that gets bigger near the fluid flow end 22 b of the passageway 22. FIG. 10 has a passageway 22 that gets bigger near the chamber end 22 a of the passageway. As can be understood from this teaching, a variety of passageway paths and sectional shapes can be utilized. For example, such sectional shapes can include circles, squares, rectangles, triangles and other various sectional shapes similar to that of the varying chamber shapes shown in FIGS. 5, 6 and 7.

The length of the passageway 22 is important because it reduces any turbulence that may be present in the flow of the fluid media and prevents it from being transmitted to the gel 40. The length 22 c of the passageway 22 needed can vary due to a variety of factors such as viscosity of the fluid media, pressure of the fluid media, flow rate of the fluid media, diameter of the passageway itself. Therefore, generally speaking the length 22 c of the passageway should be at least 5 to 8 times the (average) diameter/width 22 d of the passageway. By having such a long passageway length, this prevents erosion of the gel 40 and adds to the longevity of the pressure sensor 10. This is because the fluid media that comes into direct contact with the viscous gel is not turbulent, but rather is stagnant. In other words, a stagnation zone is created in direct contact with the viscous gel.

As shown in FIGS. 9 and 10 the diameter/width 22 d of the passageway is changing. Therefore, an average diameter 22 d is taken as the average diameter over the entire length of the passageway, such that all the diameters along the length of the passageway are summed and divided by the passageway length to result in an average diameter. Likewise, an average width of the passageway is taken as the average width over the entire length of the passageway, such that all the widths along the length of the passageway are summed and divided by the passageway length to result in an average width.

The housing 12 can be manufactured from various metals, composites, polymers or combinations thereof. In one embodiment, the housing 12 is an injection molded polymer housing. Furthermore, the injection molded polymer housing may be clear. Then, the viscous gel 40 can include a coloring or dye, such that it is easy to visually verify whether the viscous gel 40 has properly been formed within the chamber 20.

As shown in FIG. 4, the housing 12 may include a second temperature sensor 46. The distal and sensing end of the second temperature sensor may be at least partially exposed at the distal end of the housing such that it is exposed to the fluid flow. As one can see in FIG. 4, the second temperature sensor 46 is not in fluidic communication with the passageway 22 or the chamber 20.

The printed circuit board (PCB) 26 contains the pressure sensor bridge 28 and the temperature sensor 30 in close proximity to each other. The temperature sensor reading is used to measure the temperature of the gel which is similar to the temperature of the pressure sensor at the face of the bridge. The temperature reading is used as an input to the microprocessor for temperature compensation calculations. This is desired because the pressure sensor itself can change its reading based on the temperature, so it is needed to know the temperature of the pressure sensor so accurate readings can be determined for temperature compensation calculations.

The novel design disclosed herein results in an economical, durable and environmentally friendly pressure sensor that uses the pressure transmitting gel as insulation of its electrical/electronic components. The pressure sensor may be used for measurement of fluids (fluids including liquids and/or gasses) such as being suitable for use in potable water applications.

In other words, one may want to drink from the water in which the pressure sensor 10 is being utilized. Therefore, the gel 40 of the present invention is and should be able to pass any local drinking water guidelines necessary. Stringent potable water contamination guidelines are an additional compelling reason that restricts substantial exposure of foreign elements to water which the present invention satisfies. The present invention has used gels approved for use with potable water systems. It is also understood that the type of gel may change depending on the end use of different fluid media to be sensed. Furthermore, different types and viscosities of the viscous gel change the accuracy range of the pressure to be detected.

The pressure sensor 28 and temperature sensor 30 outputs are inputted to a microprocessor. The microprocessor deploys the input signals in temperature compensation algorithms that is initially calibrated under controlled conditions. Specialized mathematical algorithms are deployed in temperature compensation calculations. The microprocessor output signal may be analog or digital. An accurate pressure of the fluid flow can then be accurately calculated. It is noted that the second temperature is an optional component and that the present invention can work with only the first temperature sensor 30.

Generally, flow of liquid through a cross section of a pipe is not even, assuming laminar flow of the media. Flow is largest (fastest) at the center of the pipe and much smaller along the wall of the pipe. This is referred to as the parabolic velocity profile as shown in FIG. 11. Shape of the velocity profile is also dependent of the speed of the media through the pipe. The profile tends to get longer as the viscosity of the liquid increases. This is logical because fluid sticks more to the inner wall of the pipe. As shown in FIG. 12 by increasing the diameter of the pipe/cylinder the same media will have a shallower profile.

In the same respects, to insure even pressure across the surface of pressure sensor 28, the balance between the gel viscosity and chamber area has to be maintained. The present invention uses Dow Corning Sylgard 527 Silicone Dielectric Gel. This is a Polydinerhylsiloxane gel. Viscosity of the gel after mixing and curing is 465 cP.

Selection of the type and viscosity of the gel is dependent on several factors including: length of the chamber, diameter of the chamber, shape of the chamber, depth of gel inside the chamber, sensor surface area and target pressure range. All the above factors must be considered in design and accuracy of the sensor. For example, by increasing the viscosity of the gel, pressure sensitivity decreases, so does the shape of the velocity profile that effects the ratio of the chamber diameter to the surface area of the sensor wafer. In the target pressure range for any novel sensor taught herein, the viscosity can vary plus or minus 10 percent and the present invention will still work appropriately.

As previously taught, referring back to FIG. 4, the viscous gel 40 is configured to prevent the fluid flow from contacting the pressure sensor or the first temperature sensor. Therefore, it was taught that it is important to understand that the when the viscous gel 40 is in the camber 20, the viscous gel fully and continuously in is contact with the at least one inner sidewall 44 along a portion of the chamber perimeter 43. To aid in the contact of the viscous gel 40 to the inner sidewall 44, several improvements are now taught herein below.

Referring to FIG. 13, this is a view similar to that of FIG. 4 where now the housing 12 is shown alone without any of the other corresponding parts. FIG. 14 is an enlarged sectional view of the inner sidewall 44 taken from FIG. 13 along lines 14-14. FIG. 14 shows how the inner surface 44 has been etched 45. In other words, the etching 45 creates a pitted, dimpled, irregular surface that is non-smooth such that the viscous gel 40 creates a stronger contact to aid in the pressure sensor working as designed. It is understood that this etching is applied to all of the inner surfaces 44, whether the chamber is shaped as shown in FIGS. 5A-7A or other various chamber shapes known to those skilled in the art.

The etching can be accomplished by a variety of different techniques. For example, the housing can be made from an injection molding process. The mold can have its surface etched such that it creates the similar etch pattern in each molded component. The draft angles would be sufficiently large enough to accommodate any such etched surface. Alternatively, the etching can be accomplished after the part is either machined or molded by an additional process or processes. These processes may be physical treatment of surface by sandblasting, machining, milling or chemical processes that creates uneven surfaces, or any combination thereof.

FIG. 15 is a sectional view similar to that of FIG. 14, now showing an updated version of the housing 12 with a helical inner surface 48 formed within and along the inner surface 44. Typically, for the helical inner surface to be easily applied, the chamber 20 would be cylindrical in shape as shown in 6A. Yet, it is possible to apply a helical-like inner surface to other chamber shapes as taught herein. Furthermore, it is understood that the helical inner surface could be varied between a large thread count or a fine thread count, thereby changing the overall sizing the threads formed along the inner surface 44.

FIG. 16 is a sectional view similar to that of FIG. 15, now showing an accordion-like inner surface 50 (i.e. indented profile) formed within along the inner surface 44. Again, the sizing of the accordion-like inner surface 50 could be varied between large and small sizing according the needs and functionality of the pressure sensor design. The accordion-like inner surface 50 comprises a plurality of channels 52 disposed around the inside of the inner surface 44 and disposed next to one another. These channels 52 could take on many shapes known to those skilled in the art and is not to be limited by this exact teaching. For example, the triangular-like channels could comprise circular-like channels, rectangular-like channels or any other combinations thereof.

It is also understood that the teachings of FIGS. 13 and 14 could be applied to the teachings of FIGS. 15 and 16. It is also understood that the teachings of FIGS. 13-16 teach that the inner surface 44 is non-smooth, being either etched or having the helical or accordion-like channels.

Although several embodiments have been described in detail for purposes of illustration, various modifications may be made to each without departing from the scope and spirit of the invention. Accordingly, the invention is not to be limited, except as by the appended claims.

NUMERALS

10 pressure sensor

12 housing

14 distal end, housing

16 proximal end, housing

18 seal

19 seal channel

20 chamber

20 a first end, chamber

20 b second end, chamber

20 c length, chamber

20 d width/diameter, chamber

20 v chamber volume

21 chamber area

22 passageway

22 a chamber end of passageway

22 b fluid flow end of passageway

22 c length, passageway

22 d width/diameter, passageway

24 opening, passageway

26 circuit board

28 pressure sensor

30 first temperature sensor

32 second seal

34 backing plate

36 fasteners

38 electronic wiring, circuit board

40 viscous gel

42 empty space, chamber

43 perimeter, chamber

44 at least one inner sidewall, chamber

45 etching, inner surface

46 second temperature sensor

48 helical inner surface, inner surface

50 accordion-like inner surface, inner surface

52 channels, accordion-like inner surface 

What is claimed is:
 1. An electronic pressure and temperature sensor configured for measuring a pressure and a temperature of a flow of a fluid media to be measured, comprising: a housing comprising a distal end configured to be exposed to the flow of the fluid media when in use, the distal end opposite a proximal end, wherein the proximal end is configured not to be exposed to the fluid media when in use and instead is configured to be exposed to a surrounding atmosphere; a chamber disposed within the housing having a chamber volume, the chamber volume defined by a chamber area extending along a chamber length, the chamber area formed from a chamber perimeter having at least one chamber inner sidewall, the chamber length extending between a chamber first end and a chamber second end; a passageway disposed within the housing having a passageway volume, the passageway volume defined by a passageway area extending along a passageway length, the passageway connected at a passageway first end to the chamber and connected at a passageway second end to an opening disposed at the distal end of the housing, wherein the opening is configured to be in fluidic communication with the fluid media; wherein the chamber area is larger than the passageway area; a pressure sensor disposed within the chamber at or near the chamber first end; a first temperature sensor disposed within the chamber at or near the chamber first end; a viscous gel disposed within a portion of the chamber closer to the proximal end, the viscous gel separating both the pressure sensor and the first temperature sensor apart from the passageway; wherein the viscous gel is in direct contact with the pressure sensor and the first temperature sensor; wherein the viscous gel is in direct contact with a least a portion of the chamber perimeter; wherein the viscous gel is not disposed within the passageway and is spaced at a distance apart from the chamber second end defining an empty space within the chamber configured to contain a portion of the fluid media, wherein the empty space is configured as stagnation zone of the portion of the fluid media to be in direct contact with the viscous gel; and a second temperature sensor at least partially disposed within the housing and at least partially directly exposed at the distal end of the housing to the fluid media, wherein the second temperature sensor is not disposed within the passageway or the chamber; wherein the first temperature sensor is configured to measure a temperature of the viscous gel, the temperature of the viscous gel configured for use in temperature compensation calculations used to determine the pressure of the fluid media; and wherein the second temperature sensor is configured to measure the temperature of the flow of the fluid media.
 2. The electronic pressure and temperature sensor of claim 1, including a seal formed around the housing, the seal separating the distal end of the housing from the proximal end of the housing, wherein the seal is configured to seal to a fluid pipe containing the flow of the fluid media when the electronic pressure and temperature sensor is connected to the fluid pipe.
 3. The electronic pressure and temperature sensor of claim 1, wherein the viscous gel fully encloses the pressure sensor and the first temperature sensor.
 4. The electronic pressure and temperature sensor of claim 1, wherein the viscous gel is configured to prevent the fluid media from contacting the pressure sensor or first temperature sensor.
 5. The electronic pressure and temperature sensor of claim 1, wherein the housing is an injection molded polymer housing.
 6. The electronic pressure and temperature sensor of claim 5, wherein the injection molded polymer housing is clear.
 7. The electronic pressure and temperature sensor of claim 6, wherein the viscous gel is colored.
 8. The electronic pressure and temperature sensor of claim 1, wherein the pressure sensor is an electronic bridge pressure sensor.
 9. The electronic pressure and temperature sensor of claim 1, wherein the pressure sensor and the first temperature sensor are both mounted onto a circuit board next to each other in close proximity, wherein the circuit board is attached to the proximal end of the housing.
 10. The electronic pressure and temperature sensor of claim 9, wherein the circuit board seals the chamber first end and the chamber second end is in fluidic communication with the passageway, wherein the chamber first end and the chamber second end are delimited by the at least one inner sidewall.
 11. The electronic pressure and temperature sensor of claim 1, wherein the chamber area is larger than a pressure sensing area of the pressure sensor exposed to the viscous gel.
 12. The electronic pressure and temperature sensor of claim 1, wherein the chamber area is at least three times larger than a pressure sensing area of the pressure sensor exposed to the viscous gel, the pressure sensing area being an entire extend of a sensing element.
 13. The electronic pressure and temperature sensor of claim 1, wherein the passageway length is at least five times an average diameter or an average width of the passageway.
 14. The electronic pressure and temperature sensor of claim 1, wherein the viscous gel has a viscosity of 465 cP plus or minus 10 percent.
 15. An electronic pressure and temperature sensor configured for measuring a pressure and a temperature of a flow of a fluid media to be measured, comprising: a housing comprising a distal end configured to be exposed to the flow of the fluid media when in use, the distal end opposite a proximal end, wherein the proximal end is configured not to be exposed to the fluid media when in use and instead is configured to be exposed to a surrounding atmosphere; a chamber disposed within the housing having a chamber volume, the chamber volume defined by a chamber area extending along a chamber length, the chamber area formed from a chamber perimeter having at least one chamber inner sidewall, the chamber length extending between a chamber first end and a chamber second end; a passageway disposed within the housing having a passageway volume, the passageway volume defined by a passageway area extending along a passageway length, the passageway connected at a passageway first end to the chamber and connected at a passageway second end to an opening disposed at the distal end of the housing, wherein the opening is configured to be in fluidic communication with the fluid media; wherein the chamber area is larger than the passageway area; a pressure sensor disposed within the chamber at or near the chamber first end, wherein the chamber area is larger than a pressure sensing area of the pressure sensor exposed to the viscous gel; a first temperature sensor disposed within the chamber at or near the chamber first end; a viscous gel disposed within a portion of the chamber closer to the proximal end, the viscous gel separating both the pressure sensor and the first temperature sensor apart from the passageway; wherein the viscous gel is in direct contact with the pressure sensor and the first temperature sensor, wherein the viscous gel is configured to prevent the fluid media from contacting the pressure sensor or first temperature sensor; wherein the viscous gel is in direct contact with a least a portion of the entire chamber perimeter; wherein the viscous gel is not disposed within the passageway and is spaced at a distance apart from the chamber second end defining an empty space within the chamber configured to contain a portion of the fluid media, wherein the empty space is configured as stagnation zone of the portion of the fluid media to be in direct contact with the viscous gel; and a second temperature sensor at least partially disposed within the housing and at least partially directly exposed at the distal end of the housing to the fluid media, wherein the second temperature sensor is not disposed within the passageway or the chamber; a seal formed around the housing, the seal separating the distal end of the housing from the proximal end of the housing, wherein the seal is configured to seal to a fluid pipe containing the flow of the fluid media when the electronic pressure and temperature sensor is connected to the fluid pipe; wherein the first temperature sensor is configured to measure a temperature of the viscous gel, the temperature of the viscous gel configured for use in temperature compensation calculations used to determine the pressure of the fluid media; and wherein the second temperature sensor is configured to measure the temperature of the flow of the fluid media.
 16. The electronic pressure and temperature sensor of claim 15, wherein the pressure sensor and the first temperature sensor are both mounted onto a circuit board next to each other in close proximity, wherein the circuit board is attached to the proximal end of the housing, wherein the circuit board seals the chamber first end and the chamber second end is in fluidic communication with the passageway, and wherein the chamber first end and the chamber second end are delimited by the at least one inner sidewall.
 17. The electronic pressure and temperature sensor of claim 15, wherein the chamber area is at least three times larger than a pressure sensing area of the pressure sensor exposed to the viscous gel, the pressure sensing area being an entire extend of a sensing element.
 18. The electronic pressure and temperature sensor of claim 15, wherein the passageway length is at least five times an average diameter or an average width of the passageway.
 19. An electronic pressure and temperature sensor configured for measuring a pressure and a temperature of a flow of a fluid media to be measured, comprising: a housing comprising a distal end configured to be exposed to the flow of the fluid media when in use, the distal end opposite a proximal end; a chamber disposed within the housing having a chamber volume, the chamber volume defined by a chamber area extending along a chamber length, the chamber area formed from a chamber perimeter having at least one chamber inner sidewall, the chamber length extending between a chamber first end and a chamber second end; an opening disposed at the chamber second end, wherein the opening is configured to be in fluidic communication with the fluid media; a pressure sensor disposed within the chamber at or near the chamber first end; a first temperature sensor disposed within the chamber at or near the chamber first end; a viscous gel disposed within a portion of the chamber closer to the chamber first end, wherein the viscous gel is in direct contact with and encloses the pressure sensor and the first temperature sensor, wherein the viscous gel separates both the pressure sensor and the first temperature sensor apart from the fluid media; wherein the viscous gel is spaced at a distance apart from the chamber second end defining an empty space within the chamber configured to contain a portion of the fluid media; and a second temperature sensor at least partially disposed within the housing and at least partially directly exposed at the distal end of the housing to the fluid media, wherein the second temperature sensor is not disposed within the chamber; wherein the first temperature sensor is configured to measure a temperature of the viscous gel, the temperature of the viscous gel configured for use in temperature compensation calculations used to determine the pressure of the fluid media; and wherein the second temperature sensor is configured to measure the temperature of the flow of the fluid media.
 20. The electronic pressure and temperature sensor of claim 19, wherein the empty space is configured as stagnation zone of the portion of the fluid media to be in direct contact with the viscous gel. 